WO2022023220A1 - Syringe with high pull-out resistance - Google Patents

Abstract

Disclosed is a syringe comprising: - a syringe body (1), comprising a plunger tip (2) having an elastically deformable inner wall (20) delimiting a cavity (200); - a piston mounted so as to be able to slide inside the syringe body (1) in an injection direction, and comprising a rod (3); - a plunger, arranged at a first end of the rod (3); - a snap-on head (5), arranged at a second end (31) of the rod (3), and snapped into the cavity (200) of the plunger tip (2); the snap-on head (5) having a flat abutment surface (50) that comes into abutment against the inner wall (20) of the plunger tip (2) when the piston slides in the opposite direction to the injection direction; characterised in that the snap-on head (5) comprises at least one protruding element (6), protruding from the flat abutment surface (50), and arranged to penetrate into the inner wall (20) of the plunger tip (2) when the piston slides in the opposite direction to the injection direction.

Description

HIGH STRENGTH SYRINGE Technical field

The invention relates to the technical field of syringes.

The invention finds particular application in the injection of viscoelastic gels based on hyaluronic acid, in the field of anti-aging and medical aesthetics.

State of the art

A syringe known from the state of the art comprises:

- a syringe body, intended to receive a product to be injected, and comprising a stopper; the stopper having an inner wall, elastically deformable, and delimiting a cavity; the syringe body being intended to be equipped with a needle holder;

- a piston, mounted to slide inside the syringe body in a direction of injection of the product and in an opposite direction, and comprising a rod having a first end and an opposite second end;

- A pusher, arranged at the first end of the rod;

- a ratchet head, arranged at the second end of the rod, and snapped inside the cavity of the buffer; the latching head having a flat bearing surface bearing against the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product.

We will use the term "doctor" in the following, on the understanding that it designates any user of the syringe.

Such a syringe of the state of the art is not entirely satisfactory insofar as the ratchet head is liable to come out of the cavity of the stopper when the doctor wishes to check that the needle is not in the a vein of the patient, within the framework of an application of the injection type by intradermal route. To do this, the doctor performs an aspiration by pulling on the pusher, in the opposite direction to the direction of injection of the product, over a distance typically between 5 mm and 10 mm, in order to check the absence of blood reflux. This gesture of verification by the doctor is an important precaution since any injection under the dermal plane considerably increases the risk of intravascular injection. This gesture of verification by the doctor leads to exerting a force — called tearing force — significant (for example of the order of 6 to 8 N) on the connection between the plane bearing surface of the latching head and the wall inside the stopper, especially when the product to be injected is viscous (suction effect). Such a intensity of force acting on the connection between the planar bearing surface of the ratchet head and the inner wall of the stopper, can cause a deformation of the inner wall of the stopper so great that the ratchet head can then extract itself from the cavity of the stopper, as shown in figure 1.

A person skilled in the art therefore seeks a syringe capable of withstanding a high tearing force, for example greater than or equal to 9 N, in order to secure the doctor's verification gesture.

Disclosure of Invention

The invention aims to remedy all or part of the aforementioned drawbacks. To this end, the subject of the invention is a syringe, comprising:

- a syringe body, intended to receive a product to be injected, and comprising a stopper; the stopper having an inner wall, elastically deformable, and delimiting a cavity;

- a piston, mounted to slide inside the syringe body in a direction of injection of the product and in an opposite direction, and comprising a rod having a first end and an opposite second end;

- A pusher, arranged at the first end of the rod;

- a ratchet head, arranged at the second end of the rod, and snapped inside the cavity of the buffer; the latching head having a flat bearing surface bearing against the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product; remarkable in that the latching head comprises at least one projecting element, extending projecting from the flat bearing surface, and arranged to penetrate the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product.

Definitions

- By "inner wall" means the inner surface of the stopper delimiting a cavity, the stopper being hollow.

- By "elastically deformable", we mean that the internal wall of the stopper can deform reversibly under the action of mechanical stresses (less than the elastic limit), that is to say that the internal wall of the stopper can return to its original shape when the mechanical stresses cease.

- The term "snap-fit" means an elastic interlocking between the snap-fit head and the internal wall of the stopper, inside the cavity of the stopper. - By "projecting" is meant that the element protrudes from the flat support surface so as to extend into a half-space defined by the flat support surface, the half-space extending towards the second end of the rod.

Thus, such a syringe according to the invention makes it possible to resist a greater tearing force than in the state of the art, and this thanks to the projecting element or the projecting elements which will be anchored to the internal wall of the stopper (by deforming it locally) when the piston slides in the opposite direction to the direction of injection of the product, in particular during the execution of the checking gesture by the doctor, as illustrated in figure 2.

The syringe according to the invention may comprise one or more of the following characteristics.

According to one characteristic of the invention, the or each projecting element comprises two flat surfaces forming an acute dihedral angle, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between 40° and 50°.

Definition

By "acute dihedral angle", we mean the angle between two planes defined by the two flat surfaces, between 0° and 90°.

Thus, an advantage provided by such flat surfaces is to form a pointed part allowing the projecting element to penetrate into the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product, so as to s anchor it by deforming it locally. In other words, such flat surfaces form an anchor point.

According to a characteristic of the invention, the two flat surfaces of the or each projecting element are joined together so as to form an edge.

Definition

By “forming an edge”, we mean the formation of a line of intersection between the two flat surfaces. In other words, the two flat surfaces of the or each protruding element are brought together to form a sharp edge.

Thus, an advantage obtained is to facilitate the penetration of the projecting element into the internal wall of the stopper. According to one characteristic of the invention, the or each projecting element comprises a conical or frustoconical surface having an acute cone angle, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between between 40° and 50°.

Definitions

- By “conical surface”, we mean the surface generated by a segment (generatrix) passing through a fixed point (vertex) and through a variable point describing a curve (directrix). By way of non-limiting examples, the directing curve can be a circle, an ellipse, a polygon.

- By "frustoconical surface" means a portion of the conical surface between the base and a flat section parallel to the base.

- “Acute cone angle” means the half-angle at the apex of the cone, between 0° and 90°.

Thus, an advantage provided by such a conical or frustoconical surface is to form a pointed part allowing the projecting element to penetrate into the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product, so to be anchored there by deforming it locally. In other words, such a conical or frustoconical surface forms an anchor point.

According to one characteristic of the invention, the or each protruding element forms a tooth having an acute point angle, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between 40° and 50°.

Definitions

- By "tooth" is meant two flanks joined together to form a ridge surface.

- By “acute point angle”, we mean the dihedral angle formed between the two flanks of the tooth, the dihedral angle being between 0° and 90°.

Thus, an advantage provided by such a tooth is to form a pointed part allowing the projecting element to penetrate into the internal wall of the stopper when the piston slides in the direction opposite to the direction of injection of the product, so as to anchor it by deforming it locally. In other words, such a tooth forms an anchor point. According to one characteristic of the invention, the plane bearing surface is located at a distance, denoted D, from the second end of the rod, and the or each protruding element has a height, denoted H, along the normal to the surface plane support verifying:

0.05 D < H < 0.2 D, preferably 0.06 D < H < 0.18 D.

Thus, an advantage obtained is to obtain a depth of penetration of the projecting element into the internal wall of the bumper allowing sufficient anchoring to withstand a high tearing force (for example greater than or equal to 9 N), while maintaining a not too high snapping force (eg less than 8 N) in order to engage the snapping head with the inner wall of the bumper inside the cavity of the bumper.

According to one characteristic of the invention, the syringe comprises a set of projecting elements projecting from the flat support surface, and arranged to penetrate the internal wall of the stopper when the piston slides in the direction opposite to the direction injection of the product.

Thus, an advantage obtained is to increase the resistance to the tearing force by increasing the number of protruding elements.

According to a feature of the invention, the projecting elements of the assembly form periodically spaced patterns on the flat bearing surface.

Definition

By “periodically spaced”, we mean that the patterns repeat (preferably identically) according to a given pitch, that is to say according to a given spatial period.

Thus, an advantage obtained is to increase the adhesion of the protruding elements to the internal wall of the bumper (knurling effect), and thereby to increase the resistance to the tearing force.

According to one characteristic of the invention, the flat bearing surface is circular, and the set of projecting elements is distributed uniformly around the flat bearing surface.

Definition

By "uniformly distributed", it is meant that the projecting elements of the assembly are arranged according to an invariable radial distance with respect to the center of the circular planar surface, and are distributed around the planar support surface according to a uniform law in a manner to form an angle of 2p/N radians, where N is the number of projecting elements in the set. Thus, an advantage procured by such a geometry is to increase the resistance to the tearing force.

According to one feature of the invention, the snap-in head extends along a longitudinal axis, and the projecting elements of the assembly have axial symmetry with respect to the longitudinal axis.

Thus, an advantage provided by such a geometry is to increase the resistance to the tearing force.

According to one characteristic of the invention, the flat bearing surface has a radius, denoted R, and the or each projecting element has a lateral end located at a radial distance, denoted r, verifying:

0.8 R < r < 1.20 R, preferably R < r < 1.16 R.

Definition

By "radial distance" is meant the distance of the lateral end from the center of the flat bearing surface.

Thus, an advantage obtained is to limit the snapping force necessary to engage the snapping head with the internal wall of the stopper inside the cavity of the stopper, while reducing the risks of breaking the lateral ends of the projecting elements. when snapping.

According to one characteristic of the invention, the or each projecting element and the snap-fastening head are in one piece.

Thus, an advantage obtained is to facilitate their manufacture, which can be carried out by molding.

According to one characteristic of the invention, the snap-in head and the projecting element(s) are made of a plastic material, preferably a thermoplastic, more preferably polycarbonate.

According to one characteristic of the invention, the stopper is made of an elastomeric material, preferably a chlorinated or brominated butyl rubber. According to one characteristic of the invention, the inner wall of the stopper comprises at least one shoulder against which the planar bearing surface of the latching head comes to bear when the piston slides in the direction opposite to the direction of injection of the product. ; and the projecting element or elements are arranged to penetrate into the shoulder when the piston slides in the direction opposite to the direction of injection of the product.

Thus, an advantage provided by the shoulder is to form a support for the latching head when the piston slides in the direction opposite to the direction of injection of the product.

Brief description of the drawings

Other characteristics and advantages will appear in the detailed description of various embodiments of the invention, the description being accompanied by examples and references to the attached drawings.

Figure 1 is a partial schematic view, in section, of a syringe according to the state of the art, where the insert illustrates a significant deformation of the internal wall of the stopper, the ratchet head then being able to be extracted from the bumper cavity when the tearing force is high.

Figure 2 is a partial schematic view, in section, of a syringe according to the invention, where the insert illustrates a protruding element which is anchored to the internal wall of the stopper (by deforming it locally) when the piston slides along the direction opposite to the direction of injection of the product.

Figure 3 is a schematic view, in perspective, of a syringe according to the invention, illustrating separately the syringe body provided with a stopper and the piston provided with a snap-in head (the projecting elements are not clearly visible by their size).

Figures 4a to 4c are schematic views (respectively in perspective, in section and on an enlarged scale) of a snap-fitting head equipping a syringe of the state of the art.

Figures 5a to 5c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a snap-fitting head equipping a syringe according to the invention, illustrating a first embodiment salient elements. Figure 5c is an enlarged perspective view of area A of Figure 5b.

Figures 6a to 6c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a snap-fitting head equipping a syringe according to the invention, illustrating a second embodiment salient elements. Figure 6c is an enlarged perspective view of area B of Figure 6b.

Figures 7a to 7c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a latching head equipping a syringe according to the invention, illustrating a third embodiment of the projecting elements. Figure 7c is an enlarged perspective view of area C of Figure 7b.

Figures 8a to 8c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a snap-fitting head equipping a syringe according to the invention, illustrating a fourth embodiment salient elements. Figure 8c is an enlarged perspective view of area D of Figure 8b.

Figures 9a to 9c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a snap-fitting head equipping a syringe according to the invention, illustrating a fifth embodiment salient elements. Figure 9c is an enlarged perspective view of area E of Figure 9b.

Figures 10a to 10c are schematic views (respectively in section on an enlarged scale, in perspective and in perspective on an enlarged scale) of a snap-fitting head equipping a syringe according to the invention, illustrating a sixth embodiment salient elements. Figure 10c is an enlarged perspective view of area F of Figure 10b.

Figure 11 is a synoptic diagram (in section) of a test bench for measuring the tearing force for extracting the ratchet head from the internal wall of the buffer.

Figure 12 is a block diagram (in section) of a test bench for measuring the latching force required for fitting the latching head inside the buffer cavity.

It should be noted that the drawings described above are schematic, and are not necessarily to scale for the sake of readability and to simplify their understanding. The cuts are made along the longitudinal axis of the stem.

Detailed description of embodiments

Elements that are identical or provide the same function will bear the same references for the different embodiments, for the sake of simplification.

An object of the invention is a syringe, comprising:

- A syringe body 1, intended to receive a product to be injected, and comprising a stopper 2; the stopper 2 having an internal wall 20, elastically deformable, and delimiting a cavity 200; - A piston, mounted to slide inside the syringe body in a direction of injection of the product and in an opposite direction, and comprising a rod 3 having a first end 30 and a second opposite end 31;

- A pusher 4, arranged at the first end 30 of the rod 3;

- A snap-in head 5, arranged at the second end 31 of the rod 3, and snapped inside the cavity 200 of the stopper 2; the latching head 5 having a flat bearing surface 50 bearing against the internal wall 20 of the stopper 2 when the piston slides in the direction opposite to the direction of injection of the product; noteworthy in that the latching head 5 comprises at least one projecting element 6, extending projecting from the flat support surface 50, and arranged to penetrate the internal wall 20 of the stopper 2 when the piston slides along the direction opposite to the direction of injection of the product.

Different shapes and different arrangements of the projecting element or elements are illustrated in FIGS. 5a to 5c, 6a to 6c, 7a to 7c, 8a to 8c, 9a to 9c, 10a to 10c.

Syringe body

Syringe body 1 has:

- a first end 10, intended to be equipped with a needle holder;

- A second end 11, opposite.

The first and second ends 10, 11 of the syringe body 1 are open. The first end 10 of the syringe body 1 is open to receive a needle holder. In the absence of a needle holder, the first end 10 of the syringe body 1 can be obstructed by a cap. The second end 11 of the syringe body 1 is open to receive the plunger. The syringe advantageously comprises gripping fins, arranged at the second end 11 of the body 1 of the syringe.

Syringe body 1 is preferably cylindrical. Syringe body 1 is preferably made of a plastic material, more preferably a thermoplastic material. By way of non-limiting example, the body 1 of the syringe can be made of poly carbonate.

By way of non-limiting example, the product to be injected can be a viscoelastic gel based on hyaluronic acid.

Bumper

The inner wall 20 of the stopper 2 advantageously comprises at least one shoulder 21 against which the planar bearing surface 50 of the latching head 5 comes to bear when the piston slides in the direction opposite to the direction of injection of the product. When the latching head 5 is snapped inside the cavity 200 of the stopper 2, the stopper 2 forms a piston head. By way of non-limiting example, when the stopper 2 is in the end-of-travel position, the rod 3 can project from the body 1 of the syringe over a distance of between 20 mm and 30 mm.

The stopper 2 is advantageously made of an elastomeric material, preferably a chlorinated or brominated butyl rubber. The stopper 2 is made of a soft material, advantageously having a hardness of between 45 Shore A and 60 Shore A.

Piston rod

The rod 3 is preferably made of a plastic material, more preferably a thermoplastic material. By way of non-limiting example, the rod 3 can be made of poly carbonate. The rod 3 extends along a longitudinal axis Z'-Z.

push button

The pusher 4 and the rod 3 can be in one piece. The pusher 4 advantageously has a mass of less than or equal to 10 grams so as not to unnecessarily weigh down the syringe.

Latching head

The flat bearing surface 50 is located at a distance, denoted D, from the second end 31 of the rod 3. By way of non-limiting example, the distance D may be between 3 mm and 4 mm, preferably between between 3.2mm and 3.6mm. The flat support surface 50 can be circular, and have a radius, denoted R. By way of non-limiting example, the radius R can be between 1 mm and 1.5 mm.

The latching head 5 extends along the longitudinal axis Z′-Z.

The or each projecting element 6 and the snap-fastening head 5 are advantageously one-piece, preferably obtained by molding. The latching head 5 and the protruding element or elements 6 are advantageously made of a plastic material, preferably a thermoplastic, more preferably polycarbonate. The latching head 5 and the projecting element or elements 6 are made of a hard material, advantageously having a hardness of between 60 Shore D and 90 Shore D.

Shape of the protruding element(s)

According to one embodiment, the or each projecting element 6 comprises two flat surfaces 60, 61 forming an acute dihedral angle a, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between between 40° and 50°. As illustrated in Figures 6a to 6c, 7a to 7c, 8a to 8c, 9a to 9c, the two flat surfaces 60, 61 of the or each projecting element 6 can be joined together so as to form an edge, i.e. a sharp edge. According to an alternative illustrated in FIGS. 5a to 5c and 10a to 10c, the two flat surfaces 60, 61 of the or each projecting element 6 can be joined together so as to form a rounded edge. The line of intersection (real or virtual) of the dihedral angle a is oriented on the side of the rod 3.

According to a non-illustrated embodiment, the or each projecting element 6 comprises a conical or frustoconical surface having an acute cone angle, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between 40° and 50°. The vertex (real or virtual) of the cone of the conical or frustoconical surface is oriented on the side of the stem 3.

According to a non-illustrated embodiment, the or each protruding element 6 forms a tooth having an acute point angle, preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between 40° ° and 50°. The crest surface of the tooth is oriented towards the side of the stem 3.

Arrangement of the projecting element(s)

The or each protruding element 6 has a height, denoted H, along the normal to the flat bearing surface 50 advantageously verifying:

0.05 D < H < 0.2 D, preferably 0.06 D < H < 0.18 D.

When the planar bearing surface 50 of the snap-fastening head 5 is circular, the or each projecting element 6 has a lateral end located at a radial distance, denoted r, verifying:

0.8 R < r < 1.20 R, preferably R < r < 1.16 R.

The syringe may comprise a set of projecting elements 6 projecting from the flat bearing surface 50, and arranged to penetrate the internal wall 20 of the stopper 2 when the piston slides in the direction opposite to the direction of injection. of the product.

According to an embodiment not illustrated, the protruding elements 6 of the assembly can form periodically spaced patterns on the support surface 50 flat. By way of non-limiting example, the patterns can be arranged on the flat bearing surface 50 so as to delimit radial streaks and form a knurling.

When the flat support surface 50 is circular, the set of projecting elements 6 is advantageously distributed uniformly around the flat support surface 50. It is possible to have an even number or an odd number of projecting elements 6 distributed uniformly around the support surface 50 flat.

The projecting elements 6 of the assembly advantageously have axial symmetry with respect to the longitudinal axis Z′-Z of the snap-fastening head 5. In the case where the inner wall 20 of the stopper 2 comprises at least one shoulder 21 against which the flat bearing surface 50 of the latching head 5 comes to bear when the piston slides in the direction opposite to the direction of injection of the product, the protruding element or elements 6 are then advantageously arranged to penetrate into the shoulder 21 when the piston slides in the direction opposite to the direction of injection of the product.

As illustrated in FIGS. 10a to 10c, the snap-fastening head 5 may comprise at least one additional protruding element 6', extending projecting from a lateral edge 51 of the snap-fastening head 5, and arranged to penetrate into the inner wall 20 of stopper 2 when the piston slides in the direction opposite to the direction of injection of the product.

Test benches

The test bench 7 schematically illustrated in FIG. 11 makes it possible to measure the tearing force to extract the snap-fastening head 5 from the internal wall 20 of the stopper 2. The test bench 7 comprises a plate 70 comprising walls 700 , forming a jaw, and arranged to hold the syringe in position by gripping it. The stopper 2 is fixed to the body 1 of the syringe (for example at the first end 10 of the body 1 of the syringe), preferably using a strong glue. The test bench 7 comprises an actuator 71 arranged to pull the pusher 4 (traction movement) until the snapping head 5 is pulled out of the stopper 2. The actuator 71 is configured to move at a speed representative of the speed of execution of the doctor's verification gesture, over a predetermined distance. The force generated by the actuator 71 is measured by a sensor during the traction movement. The maximum value of the force generated by the actuator 71 is retained as the tearing force value.

The test bench 7 schematically illustrated in FIG. 12 makes it possible to measure the latching force necessary for fitting the latching head 5 inside the cavity 200 of the stopper 2. The test bench 7 comprises a plate 70 comprising walls 700, forming a jaw, and arranged to hold the syringe in position by gripping it. The stopper 2 is introduced at the bottom of the body 1 of the syringe (at the first end 10 of the body 1 of the syringe). The test bench 7 includes an actuator 71 arranged to push on the pusher 4 (compression movement) until the latching of the latching head 5 inside the cavity 200 of the stopper 2. The force generated by the actuator 71 is measured by a sensor during the compression movement. The latching of the latching head 5 inside the cavity 200 of the stopper 2 leads to a force peak generated by the actuator 71. The maximum value of the force peak generated is measured, and retained as the snapping force value. For a syringe according to the invention, the measured pull-out force can be between 11.8 N and 12.5 N, with a measured latching force between 6.8 N and 8.6 N.

The invention is not limited to the disclosed embodiments. The person skilled in the art is able to consider their technically effective combinations, and to substitute them with equivalents.

Claims

1. Syringe, comprising: - a syringe body (1), intended to receive a product to be injected, and comprising a stopper (2); the stopper (2) having an internal wall (20), elastically deformable, and delimiting a cavity (200); - a piston, mounted to slide inside the body (1) of the syringe in a direction of injection of the product and in an opposite direction, and comprising a rod (3) having a first end (30) and a second end ( 31) opposite; - a pusher (4), arranged at the first end (30) of the rod (3); - a ratchet head (5), arranged at the second end (31) of the rod (3), and snapped inside the cavity (200) of the stopper (2); the latching head (5) having a flat bearing surface (50) bearing against the internal wall (20) of the stopper (2) when the piston slides in the direction opposite to the direction of injection of the product; characterized in that the snap-fastening head (5) comprises at least one projecting element (6), projecting from the plane support surface (50), and arranged to penetrate into the internal wall (20) of the stopper (2) when the piston slides in the direction opposite to the direction of injection of the product. 2. Syringe according to claim 1, in which the or each projecting element (6) comprises two flat surfaces (60, 61) forming an acute dihedral angle (a), preferably between 10° and 80°, more preferably between 30° and 60°, even more preferably between 40° and 50°. 3. Syringe according to claim 2, in which the two flat surfaces (60, 61) of the or each projecting element (6) are joined together so as to form an edge. 4. Syringe according to claim 1, in which the or each projecting element (6) comprises a conical or frustoconical surface having an acute cone angle, preferably between 10° and 80°, more preferably between 30° and 60° , even more preferably between 40° and 50°. 5. Syringe according to claim 1, in which the or each protruding element (6) forms a tooth having an acute point angle, preferably between 10° and 80°, plus preferably between 30° and 60°, even more preferably between 40° and 50°. 6. Syringe according to one of claims 1 to 5, wherein the flat bearing surface (50) is located at a distance, denoted D, from the second end (31) of the rod (3), and the or each protruding element (6) has a height, denoted H, along the normal to the plane support surface (50) verifying: 0.05 D < H < 0.2 D, preferably 0.06 D < H < 0.18 D. 7. Syringe according to one of claims 1 to 6, comprising a set of projecting elements (6) extending projecting from the flat support surface (50), and arranged to penetrate the internal wall (20) of the stopper (2) when the piston slides in the direction opposite to the direction of injection of the product. 8. A syringe according to claim 7, wherein the protrusions (6) of the assembly form periodically spaced patterns on the flat bearing surface (50). 9. Syringe according to claim 7 or 8, in which the flat support surface (50) is circular, and the set of projecting elements (6) is distributed uniformly around the flat support surface (50). 10. Syringe according to one of claims 7 to 9, wherein the snap-fastening head (5) extends along a longitudinal axis (Z'-Z), and the projecting elements (6) of the assembly have a axial symmetry with respect to the longitudinal axis (Z'-Z). 11. Syringe according to one of claims 1 to 10, in which the planar support surface (50) has a radius, denoted R, and the or each projecting element (6) has a lateral end located at a radial distance, denoted r, verifying: 0.8 R < r < 1.20 R, preferably R < r < 1.16 R. 12. Syringe according to one of claims 1 to 11, wherein the or each projecting element (6) and the snap-fastening head (5) are in one piece. 13. Syringe according to one of claims 1 to 12, wherein the snap-in head (5) and the projecting element(s) (6) are made of a plastic material, preferably a thermoplastic, more preferably polycarbonate. 14. Syringe according to one of claims 1 to 13, wherein the stopper (2) is made of an elastomeric material, preferably a chlorinated or brominated butyl rubber. 15. Syringe according to one of claims 1 to 14, wherein the internal wall (20) of the stopper (2) comprises at least one shoulder (21) against which abuts the flat support surface (50) of the ratchet head (5) when the piston slides in the direction opposite to the direction of injection of the product; and the projecting element(s) (6) are arranged to penetrate into the shoulder (21) when the piston slides in the direction opposite to the direction of injection of the product.